Abstract
The spatial organization and dynamics of a genome are central to gene regulation. While a comprehensive understanding of chromatin organization in the human nucleus has been achieved using fixed-cell methods, measuring the dynamics of specific genomic regions over extended periods in individual living cells remains challenging. Here, we present a robust and fully genetically encoded system for fluorescent labeling and long-term tracking of any accessible non-repetitive genomic locus in live human cells using fluorogenic and replenishable nanobody array fusions of the Staphylococcus aureus dCas9, and compact polycistronic single guide (sg)RNAs. First, we characterize the selectivity and photostability of our probes, enabling genome-wide visualization of chromatin dynamics at locally repetitive elements. Next, through multiplexed expression of 8–10 sgRNAs from polycistronic cassettes, we demonstrate efficient and sustained labeling of non-repetitive loci, enabling high-fidelity tracking of gene-proximal regions at exceptional spatial and temporal resolution. Finally, by correlating chromatin mobility with transcriptional activity at multiple genes, we find that local chromatin dynamics at 20 Hz are gene-specific and not necessarily dependent on transcription. Our approach is versatile, minimally invasive, and scalable, enabling multiplexed imaging of regulatory element dynamics involved in gene control, with broad applicability across diverse biological systems and disease contexts.
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Abstract
The spatial organization and dynamics of a genome are central to gene regulation. While a comprehensive understanding of chromatin organization in the human nucleus has been achieved using fixed-cell methods, measuring the dynamics of specific genomic regions over extended periods in individual living cells remains challenging. Here, we present a robust and fully genetically encoded system for fluorescent labeling and long-term tracking of any accessible non-repetitive genomic locus in live human cells using fluorogenic and replenishable nanobody array fusions of the Staphylococcus aureus dCas9, and compact polycistronic single guide (sg)RNAs. First, we characterize the selectivity and photostability of our probes, enabling genome-wide visualization of chromatin dynamics at locally repetitive elements. Next, through multiplexed expression of 8–10 sgRNAs from polycistronic cassettes, we demonstrate efficient and sustained labeling of non-repetitive loci, enabling high-fidelity tracking of gene-proximal regions at exceptional spatial and temporal resolution. Finally, by correlating chromatin mobility with transcriptional activity at multiple genes, we find that local chromatin dynamics at 20 Hz are gene-specific and not necessarily dependent on transcription. Our approach is versatile, minimally invasive, and scalable, enabling multiplexed imaging of regulatory element dynamics involved in gene control, with broad applicability across diverse biological systems and disease contexts.
Competing Interest Statement
The authors have declared no competing interest.
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